Fully buffered DIMM read data substitution for write acknowledgement

ABSTRACT

A memory controller uses a scheme to retire two entries from a replay queue due to a single non-error response. Advantageously, entries in a replay queue may be retired earlier than conventional systems, minimizing the size of the replay queue.

FIELD OF THE INVENTION

This present invention relates generally to memory systems, components, and methods, and more particularly to fully buffered memory controllers that efficiently retire entries in a replay queue.

BACKGROUND OF THE INVENTION

Conventional computer memory subsystems are often implemented using memory modules. A computer circuit board is assembled with a processor having an integrated memory controller, or coupled to a separate memory controller. The processor having the integrated memory controller or the separate memory controller is connected by a memory bus to one or more memory module electrical connectors (the bus may also connect to additional memory permanently mounted on the circuit board). System memory is configured according to the number of and storage capacity of the memory modules inserted in the electrical connectors.

As processor speeds have increased, memory bus speeds have been pressured to the point that the multi-point (often referred to as “multi-drop”) memory bus model no longer remains viable. Referring to FIG. 1, one current solution uses a “point-to-point” memory bus model employing buffered memory modules. In FIG. 1, a computer system 100 comprises a host processor 105 communicating across a front-side bus 108 with a memory controller 110 that couples the host processor to various peripherals (not shown except for system memory). Memory controller 110 communicates with a first buffered memory module 0 across a high-speed point-to-point bus 112. A second buffered memory module 1, when included in system 100, shares a second high-speed point-to-point bus 122 with first memory module 0. Additional high-speed point-to-point buses and buffered memory modules can be chained behind memory module 1 to further increase the system memory capacity.

Buffered memory module 0 is typical of the memory modules. A memory module buffer (MMB) 146 connects module 0 to a host-side memory channel 112 and a downstream memory channel 122. A plurality of memory devices (Dynamic Random Access Memory Devices, or “DRAMs” like DRAM 144, are shown) connect to memory module buffer 146 through a memory device bus (not shown in FIG. 1) to provide addressable read/write memory for system 100.

As an exemplary memory transfer, consider a case in which processor 105 needs to access a memory address corresponding to physical memory located on memory module 1. A memory request issues to memory controller 110, which then sends a memory command, addressed to memory module 1, out on host memory channel 112. Memory controller 110 also designates an entry 115 corresponding to the memory command into replay queue 111. Prior entries corresponding to prior memory commands may be ahead of entry 115 in queue 111.

For tractability reasons, entry 115 may be retired from the queue 111 only after two conditions are met. First, memory controller 110 only retires an entry after a corresponding non-error response is received. Second, memory controller 110 only retires an entry if all prior entries have been retired.

The MMB 146 of buffered memory module 0 receives the command, resynchronizes it, if necessary, and resends it on memory channel 122 to the MMB 148 of buffered memory module 1. MMB 146 detects that the command is directed to it, decodes it, and transmits a DRAM command and signaling to the DRAMs controlled by that buffer. If the memory transfer was successful, MMB 148 sends a non-error response through memory module 0 back to memory controller 110. Memory controller 110 retires entry 115 from replay queue 111 after the non-error response is received, but only if all prior entries have also been retired.

Due to economies, the size of the replay queue 111 is limited. Therefore, entries need to be retired as quickly as possible. Due to northbound bandwidth limitations of high-speed point-to-point bus 112, receipt of non-error responses such as write acknowledges may be delayed. Delayed receipt of such a write acknowledgement may in turn delay the retirement of subsequent entries that were entered into replay queue 111 after entry 115. The delayed retirement of an entry and subsequent entries limits the amount of space available in replay queue 111 for new entries.

Because of the forgoing limitations, the amount of free space in replay queues of memory controllers is limited. The disclosure that follows solves this and other problems.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing a conventional memory controller.

FIG. 2 is a diagram of a memory controller that retires two entries from a replay queue in response to a single non-error response.

FIG. 3 is a flowchart showing how the memory controller of FIG. 2 retires the entries.

FIG. 4A is a timing diagram showing the operation illustrated in FIG. 2.

FIG. 4B is a timing diagram showing an alternative operation of the memory controller of FIG. 2.

DETAILED DESCRIPTION

FIG. 2 shows one example of a memory controller 200 that retires two replay queue entries according to a single non-error response. The memory controller 200 includes an issue engine 201, a memory 202 and a replay queue 203. The issue engine 201 performs the functions described in the flowcharts of FIG. 3. The timing of the signals shown in FIG. 2 is depicted in the timing diagram in FIG. 4 a.

Memory controller 200 sends memory command 204 a to memory module 1. In this example memory command 204 a is a burst length eight read command including a starting address for a multicycle read operation. In other examples memory command is any type of read command. An entry 204 b corresponding to memory command 204 a is created in replay queue 203. Upon receiving memory command 204 a, memory module 1 starts reading data beginning with the start address. As memory module 1 is reading data, it sends back the read data in non-error memory response 204 c.

Next memory controller 200 sends memory command 205 a to memory module 0 that is north of memory module 1. In this example memory command 205 a is a burst length four write command that provides write data to memory module 0 during four successive strobes. In other examples memory command 205 a is any type of write command. An entry 205 b corresponding to memory command 205 a is created in replay queue 203. Entry 205 b is a consecutive entry with respect to entry 204 b. Upon receiving memory command 205 a, memory module 0 begins writing the data provided with memory command 205 a. Memory module 0 begins writing data concurrently with memory module 1 reading data according to memory command 204 b.

Memory controller 200 sends memory command 206 a to memory module 1 that is south of memory module 0. Memory command 206 a is a burst read command similar to memory command 204 a. An entry 206 b corresponding to memory command 206 a is created in replay queue 203.

Memory module 0 finishes writing data according to the burst length four write command 205 a. However, since memory module 1 is still sending read data via Memory Module Buffer (MMB) 245 of memory module 0 there is no bandwidth available for memory module 0 to send a non-error response 205 c. The non-error response 204 c including the read data consumes all of the bandwidth in the northbound direction. Accordingly, the memory controller 200 does not observe a non-error response including a write acknowledgement at this time.

After data is read according to memory command 204 a, memory module 1 begins reading data according to memory command 204 c. As memory module 1 is reading data, it sends back the read data in non-error memory response 206 c. Non-error response 206 c consumes all of the bandwidth in the northbound direction and is sent immediately after non-error responses 204 c. According to conventional FBD protocol, memory controller 200 must continue to wait to observe non-error response 205 c until bandwidth is available. As used within the specification, the FBD protocol refers to, for example, any revision of the FBD specification on the JEDEC website. Non-error response 205 c may include explicit signals such as idle patterns or write acknowledgements.

Memory controller 200 receives non-error response 204 c. Entry 204 b is retired from the replay queue 203 because there are no prior entries pending. Although memory controller 200 has not received an explicit non-error response 205 c corresponding to entry 205 b, memory controller 200 may also retire entry 205 b in response to non-corresponding non-error response 204 c. This is in contrast to conventional FBD protocol where memory controller 200 must continue to wait for non-error response 205 c. Thus two entries may be retired in response to a single non-error response 204 c.

Entry 205 b may be retired upon receipt of non-corresponding non-error response 204 c because of the following occurrences. First, entry 205 b corresponds to a write to a memory module that is north of a memory module that was read. Second, the write occurs concurrently with the read from the southern memory module. Third, an alert corresponding to memory command 205 a was not received. An alert corresponding to memory command 205 a would have taken priority over non-error response 204 c. Accordingly, the receipt of non-error response 204 c implicitly signals memory controller 200 that an alert was not issued and that memory command 205 a must have been successful. Thus, entry 205 b may be advantageously retired early before a corresponding non-error response 205 c is received.

Next non-error response 206 c is received. Entry 206 b may advantageously be retired immediately because there are no prior entries in memory queue 203. Had memory controller 200 waited for a corresponding non-error response 205 c before retiring entry 205 b, prior entry 205 b would exist causing a delay in retiring 206 b. Thus memory controller 200 retires entries 205 b and 206 b early compared to a conventional memory controller.

Finally, non-error response 205 c including a write acknowledgement may be received. Since memory controller 200 has already been signaled that memory command 205 a was successful, memory controller 200 may forgo observation of explicit non-error response 205 c. Optionally forgoing explicit write acknowledgement 205 c due to the presence of the aforementioned occurrences advantageously increases southbound occupancy. The increase in southbound occupancy increases maximum bandwidth by as much as 50% over conventional systems with similar replay queue limitations.

The above process is illustrated in a flowchart in FIG. 3. Referring to FIG. 3, the memory controller 200 issues a read command to cause a first memory module to be read in block 300. In block 301, a write command is issued to cause a second memory module that is farther north than the first memory module to be concurrently written. Next the memory controller 200 creates a first entry corresponding to the read command in a replay queue 203 in block 302. In block 303 a second entry is created corresponding to the write command.

Next, in block 304 the memory controller 200 waits for a non-error response corresponding to the read command. If the non-error response is received in block 305, the memory controller 200 retires both entries in block 306A. If the non-error response is not received, in block 306B memory controller 200 resets the branch and then replays the contents of replay queue 203.

FIG. 4A shows a timing diagram for the system illustrated in FIG.2. DIMM 1 receives a read command 204 a from memory controller 200 and begins reading data at T₆. DIMM 0 receives a write command 205 a and begins writing data at T₇ concurrently with DIMM 1 reading data. As DIMM 1 is reading data a transmission 204 c from DIMM 1 begins at T₇. Transmission 204 c continues up to T₁₀, thereby preventing the memory controller 200 from immediately observing an explicit write acknowledge 205 c.

Meanwhile, DIMM 1 receives a read command 206 a from memory controller 200 at T₉ and begins reading. Immediately after DIMM 1 completes transmission 204 c, transmission 206 c begins at T₁₁. Memory controller 200 is still unable to observe an explicit write acknowledgement 205 c because transmissions 204 c and 206 c consume all of the northbound bandwidth.

Meanwhile, memory controller 200 starts receiving the read data transmission 204 c from DIMM 1 at T₈. When the transmission is completed at T₁₁, memory controller 200 retires entry 204 b from the replay queue 203. Memory controller 200 also retires entry 205 b from the replay queue 203 in response to receiving non-corresponding non-error response 204 c. Non-corresponding non-error response 204 c was not sent in response to memory command 205 a and does not correspond to entry 205 b. Nonetheless, entry 205 b is retired. Finally, at T₁₅ memory controller 200 receives non-error response 206 c and retires entry 206 b.

It is not necessary for memory controller 200 to observe write acknowledge 205 c at a first opening T₁₅. Bandwidth may be saved for other transmissions by forgoing explicit observation of write acknowledge 205 c.

FIG. 4B shows a timing diagram according to a different series of transmissions than illustrated in FIG. 2. The memory controller 200 causes DIMM 1 to start a first read T₆ and DIMM 0 to start writing data at T₇. The memory controller 200 also causes DIMM 0 to start a second read at T₁₀.

Memory controller 200 begins receiving a non-error response corresponding to the first read at T₈. When the complete non-error response corresponding to the first read is received at T₁₁, entries associated with the first read and the write are both retired. In other words, the entry associated with the write is retired in response to a non-corresponding non-error response. Finally, the memory controller 200 retires an entry associated with the second read at T₁₅.

The system described above can use dedicated processor systems, micro controllers, programmable logic devices, or microprocessors that perform some or all of the operations. Some of the operations described above may be implemented in software and other operations may be implemented in hardware.

For the sake of convenience, the operations are described as various interconnected functional blocks or distinct software modules. This is not necessary, however, and there may be cases where these functional blocks or modules are equivalently aggregated into a single logic device, program or operation with unclear boundaries. In any event, the functional blocks and software modules or features of the flexible interface can be implemented by themselves, or in combination with other operations in either hardware or software.

Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention may be modified in arrangement and detail without departing from such principles. I claim all modifications and variation coming within the spirit and scope of the following claims. 

1. A memory controller comprising: control logic to retire at least two entries in a retirement queue in response to a single response sent from a memory module over a point-to-point memory bus; wherein: a first entry of the at least two entries corresponds to a first memory command to cause a first memory module to read; a second entry of the at least two entries corresponds to a second memory command to cause a second memory module to write; the control logic is configured to retire the first entry and the second entry in response to the single response before receiving a response corresponding to second memory command; and the single response corresponds to the first entry and the first memory command.
 2. The memory controller of claim 1 wherein the first memory module is the memory module and is south of the second memory module.
 3. The memory controller of claim 2 wherein the single response includes data read from the first memory module.
 4. The memory controller of claim 3 wherein the second memory command directs the second memory module to write concurrently with the first memory module reading.
 5. A method comprising: sending a first memory command causing a first memory module to read; sending a second memory command causing a second memory module to write, the second memory module being farther north than the first memory module; designating a first queue entry corresponding to the first memory command and a second queue entry corresponding to the second memory command; and retiring both queue entries in response to a response originating from the first memory module before receiving a response from the second memory module corresponding to the second memory command.
 6. The method of claim 5 wherein the response includes data read from the first memory module.
 7. The method of claim 5 wherein the response does not correspond to the second memory command.
 8. The method of claim 5 wherein a write acknowledgement in response to the second memory command is not received.
 9. The method of claim 5 further comprising writing data to the second memory module concurrently with the first memory module reading.
 10. The method of claim 5 wherein the first memory command includes a burst length eight read or a back-to-back pair of open-page burst length four reads.
 11. The method of claim 5 wherein retiring both queue entries further comprises retiring both queue entries at substantially a same time.
 12. A memory apparatus comprising: control logic to receive a southbound memory read command, the control logic to forward the southbound memory read command to a memory module buffer for a memory module, to receive a memory write command, to forward to a memory controller a northbound response corresponding to the memory read command; and to determine whether to send a non-error response corresponding to the memory write command; wherein the memory controller is configured to determine that a write occurred based on the northbound response; and the memory controller is configured to retire two entries in a replay queue corresponding to the southbound memory read command and the memory write command, the memory controller to retire the two entries in response to the northbound response and before receiving a response corresponding to the memory write command.
 13. The memory apparatus of claim 12 wherein the northbound response includes data read from the memory module.
 14. A system comprising: control logic to send a first memory command to a first memory module; the first memory module to read in response to the first memory command; the control logic to send a second memory command to a second memory module, the second memory module being farther south than the first memory module; the second memory module to write in response to the second memory command; the control logic to designate a first queue entry corresponding to the first memory command and a second queue entry corresponding to the second memory command; and the control logic to retire both queue entries in response to a response originating from the first memory module before receiving a response from the second memory module corresponding to the second memory command.
 15. The system of claim 14 wherein the response includes data read from the first memory module.
 16. The system of claim 14 wherein the response does not correspond to the second memory command.
 17. The system of claim 14 wherein a write acknowledgement in response to the second memory command is not received.
 18. The system of claim 14 further comprising the control logic to write data to the second memory module concurrently with the first memory module reading.
 19. The system of claim 15 wherein the first memory command includes a burst length eight read or a back-to-back pair of burst length four reads. 